Seunguk Han scite author profile

Son

Kim

et al. 2020

Context: Patients with chronic ankle instability (CAI) have demonstrated sensorimotor impairments. Submaximal force steadiness and accuracy measure sensory, motor, and visual function via a feedback mechanism, which helps researchers and clinicians to comprehend sensorimotor deficits associated with CAI. Objective: To determine if participants with chronic ankle instability experience deficits in hip and ankle submaximal force steadiness and accuracy compared to healthy controls. Design: A case-controlled study Setting: Research Laboratory Patients and Other Participants: Twenty-one CAI patients and 21 uninjured controls participated in this study. Intervention(s): n/a. Main Outcome Measure(s): Maximal voluntary isometric contraction (MVIC), force steadiness and accuracy (10% and 30% of their MVIC) of ankle evertors, invertors, and hip abductors. The central 10-sec (20–87% of the total time) of the 3 trials were analyzed. An independent t-test was used to assess MVIC. Two-way, 2 × 3, ANOVAs were used to assess force steadiness and accuracy. Results: Relative to controls, the CAI group demonstrated lower accuracy in invertors (p =.0006). Across all motions, the CAI group showed less steadiness (p = .0005) and lower accuracy (p = .0074) than the controls in 10% MVIC. In terms of MVIC, the CAI group showed less force output in hip abduction compared with the control group (p < .0001). Conclusions: CAI patients showed an inability to control ongoing fine force (10% and 30% of their MVIC) through a feedback mechanism during an active test. These findings suggest deficits in sensorimotor control that lead CAI patients to be more susceptible to injury positions since they have difficulty integrating the peripheral information and correcting their movement in relation to visual information.

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Prelanding movement strategies among chronic ankle instability, coper, and control subjects

Son

Kim

et al. 2021

Sports Biomechanics

The effects of visual feedback disruption on postural control with chronic ankle instability

Journal of Science and Medicine in Sport

Son

et al. 2022

Altered Visual Reliance Induced by Stroboscopic Glasses during Postural Control

Hopkins

2022

IJERPH

Little is known about how disrupted vision affects visual reliance during postural control. postural control. Twenty-four physically active adults volunteered to participate in the study. Static postural control was quantified with center of pressure measures during a one-legged balance test with four different visual inputs (eyes-open (EO), high frequency of strobe vision (HSV), low frequency of strobe vision (LSV), and eyes-closed (EC)) and on two different surfaces (firm and foam). Dynamic postural control was calculated by the dynamic postural stability index and the Y-Balance test for three different visual inputs (EO, HSV, and LSV) and the two different surfaces. Romberg ratios (HSV/EO, LSV/EO, and EC/EO) were then calculated and used for statistical analysis to assess visual contribution during postural control. In the results, Romberg ratios were higher when people were on the foam surface than the firm surface in center of pressure total path in medial-lateral and anterior-posterior directions (p < 0.05, both directions). Similarly, Romberg ratios were higher on the foam surface than the firm surface in dynamic stability index in medial-lateral and anterior-posterior directions (p < 0.05, both directions). Stroboscopic glasses could alter visual reliance when the somatosensory system is disturbed by a foam pad during both static and dynamic postural control. Clinicians could use the glasses to manipulate visual reliance during dynamic balance training for patients with musculoskeletal injuries.

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Effects of balance training with stroboscopic glasses on postural control in chronic ankle instability patients

Scandinavian Med Sci Sports

Page

et al. 2021